2017

DOI: 10.1038/ncomms14875

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Naked d-orbital in a centrochiral Ni(II) complex as a catalyst for asymmetric [3+2] cycloaddition

Yoshihiro Sohtome

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Atsuya Muranaka

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et al.

Abstract: Chiral metal catalysts have been widely applied to asymmetric transformations. However, the electronic structure of the catalyst and how it contributes to the activation of the substrate is seldom investigated. Here, we report an empirical approach for providing insights into the catalytic activation process in the distorted Ni(II)-catalysed asymmetric [3+2] cycloaddition of α-ketoesters. We quantitatively characterize the bonding nature of the catalyst by means of electron density distribution analysis, showi… Show more

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Cited by 41 publications

(57 citation statements)

References 67 publications

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“…However, statistically speaking, Co would still have to have more free coordination sites than Co at the surface, because they already have three more vacant sites in the bulk. In addition, the present distortion of the geometry will promote catalysis …”

Section: Resultsmentioning

confidence: 99%

New Insights into the Catalytic Activity of Cobalt Orthophosphate Co₃(PO₄)₂from Charge Density Analysis

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et al. 2019

Chemistry A European J

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An extensive characterization of Co3(PO4)2 was performed by topological analysis according to Bader‘s Quantum Theory of Atoms in Molecules from the experimentally and theoretically determined electron density. This study sheds light on the reactivity of cobalt orthophosphate as a solid‐state heterogeneous oxidative‐dehydration and ‐dehydrogenation catalyst. Various faces of the bulk catalyst were identified as possible reactive sites given their topological properties. The charge accumulations and depletions around the two independent five‐ and sixfold‐coordinated cobalt atoms, found in the topological analysis, are correlated to the orientation and population of the d‐orbitals. It is shown that the (011) face has the best structural features for catalysis. Fivefold‐coordinated ions in close proximity to advantageously oriented vacant coordination sites and electron depletions suit the oxygen lone pairs of the reactant, mainly for chemisorption. This is confirmed both from the multipole refinement as well as from density functional theory calculations. Nearby basic phosphate ions are readily available for C−H activation.

“…However, statistically speaking, Co would still have to have more free coordination sites than Co at the surface, because they already have three more vacant sites in the bulk. In addition, the present distortion of the geometry will promote catalysis …”

Section: Resultsmentioning

confidence: 99%

New Insights into the Catalytic Activity of Cobalt Orthophosphate Co₃(PO₄)₂from Charge Density Analysis

¹

,

²

,

³

et al. 2019

Chemistry A European J

View full text Add to dashboard Cite

An extensive characterization of Co3(PO4)2 was performed by topological analysis according to Bader‘s Quantum Theory of Atoms in Molecules from the experimentally and theoretically determined electron density. This study sheds light on the reactivity of cobalt orthophosphate as a solid‐state heterogeneous oxidative‐dehydration and ‐dehydrogenation catalyst. Various faces of the bulk catalyst were identified as possible reactive sites given their topological properties. The charge accumulations and depletions around the two independent five‐ and sixfold‐coordinated cobalt atoms, found in the topological analysis, are correlated to the orientation and population of the d‐orbitals. It is shown that the (011) face has the best structural features for catalysis. Fivefold‐coordinated ions in close proximity to advantageously oriented vacant coordination sites and electron depletions suit the oxygen lone pairs of the reactant, mainly for chemisorption. This is confirmed both from the multipole refinement as well as from density functional theory calculations. Nearby basic phosphate ions are readily available for C−H activation.

“…As shown in Scheme , the centrochiral Ni(II)/diamine complex directly activated α‐ketoester 2 a through the formation of Ni(II)‐enolate intermediate 2 aa . The coordination pattern of Ni(II)‐enolate 2 aa is in the octahedral structure according to Sodeoka's model, and α‐ketoesters 2 a occupies the same plane with the chiral diamine reported by Evans . Because of the hydrogen‐bonding interactions between the NH of ligand L1 and nitro group, the nitroalkene 1 a approaches intermediate 2 aa from the back face and leads Re (C=C) face attack (transition state 2 ab ), thus forms the intermediate 2 ac .…”

Section: Methodsmentioning

confidence: 99%

Nickel(II)‐Catalyzed Diastereo‐ and Enantioselective Michael/ Hemiacetalization Cascade Reaction of α‐Ketoesters with 2‐(2‐Nitrovinyl)phenols

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et al. 2019

Adv Synth Catal

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A nickel(II)/diamine-catalyzed diastereoand enantioselective Michael/hemiacetalization cascade reaction of α-ketoesters with 2-(2-nitrovinyl) phenols has been established, thus providing a range of structurally diverse polysubstituted chromanes in good yields and excellent stereoselectivities (up to 89% yield, > 20:1 dr, > 99% ee). Moreover, the gram-scale experiment was performed with only 0.5 mol% of catalyst, and tricyclic furanobenzodihydropyran compound was gained by the derivatization of product, which showed the great synthetic potential of this strategy.

“…[73][74][75] In 2017, Sohtome, Hashizume, Sodeoka, and coworkers performed an inverse-electron-demand (IED) [3+2] cycloaddition of -keto esters 71 with C,N-cyclic nitrones catalyzed by asymmetric nickel catalysts providing chiral isoxazolidine-fused THIQs 72 bearing three contiguous stereocenters (Scheme 29). 76 The use of diamine ligands with -branched substituents improved the enantioselec-tivity, and the diamine (R,R)-L14, bearing cyclohexyl groups was the most effective. In addition, with regard to the counteranions and additives, acetate and achiral i-Pr 2 NH, to some degree, were effective in improving the enantioselectivities.…”

Section: Short Review Synthesis Scheme 27 Enantioselective Synthesis mentioning

confidence: 99%

Asymmetric Synthesis of C1-Chiral THIQs with Imines in Isoquinoline Rings

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2020

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Tetrahydroisoquinoline (THIQ) scaffolds are important structural units that widely exist in a variety of natural alkaloids and synthetic analogues. Asymmetric synthesis of C1-chiral THIQ is of particular importance due to its significant pharmaceutical, agrochemical, and other biological activities, and the usually distinct bioactivities exhibited by the two enantiomers. In this review, we highlight the significant advances achieved in this field, present recent asymmetric synthesis with imines in isoquinoline rings ordered according to the sequence of various substrate types. New strategies could be inspired and more types of substrates need further development.1 Introduction2 Catalytic Asymmetric Reaction of Dihydroisoquinolines2.1 Asymmetric Reactions of 3,4-Dihydroisoquinolines2.2 Asymmetric Reactions of Dihydroisoquinolinium Salts2.3 Asymmetric Reactions of C,N-Cyclic N′-Acyl Azomethine Imines2.3.1 NED [3+2] Cycloaddition of C,N-Cyclic N′-Acyl Azomethine Imines2.3.2 IED [3+2] Cycloaddition of C,N-Cyclic N′-Acyl Azomethine Imines2.3.3 [3+3] Cycloaddition of C,N-Cyclic N′-Acyl Azomethine Imines2.3.4 [4+3] Cycloaddition of C,N-Cyclic N′-Acyl Azomethine Imines2.3.5 Asymmetric Addition Reactions to C,N-Cyclic N′-Acyl Azomethine Imines2.4 Asymmetric Reactions of C,N-Cyclic Nitrones3 Catalytic Asymmetric Mannich Reactions of Isoquinolines4 Conclusions and Perspectives

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